DOCSLIB.ORG

Soma Compound (Carisoprodol and Aspirin Tablets, USP) Is a Fixed-Dose Combination Product Containing the Following Two Products

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Soma Compound (Carisoprodol and Aspirin Tablets, USP) Is a Fixed-Dose Combination Product Containing the Following Two Products SOMA® COMPOUND (carisoprodol and aspirin tablets, USP) for oral use DESCRIPTION Soma Compound (carisoprodol and aspirin tablets, USP) is a fixed-dose combination product containing the following two products: • 200 mg of carisoprodol, a centrally-acting muscle relaxant • 325 mg of aspirin, an analgesic with antipyretic and anti-inflammatory properties. It is available as a two-layered, white and orange, round tablet for oral administration. Carisoprodol: Chemically, carisoprodol is N-isopropyl-2-methyl-2-propyl-1,3-propanediol dicarbamate and its molecular formula is C12H24N2O4, with a molecular weight of 260.33. The structural formula of carisoprodol is: Aspirin: Chemically, aspirin (acetylsalicyclic acid) is 2-(acetyloxy)-, benzoic acid and its molecular formula is C9H8O4, with a molecular weight of 180.16. The structural formula of aspirin is: Other ingredients in the Soma Compound drug product are croscarmellose sodium, FD&C Red #40, FD&C Yellow #6, hypromellose, magnesium stearate, microcrystalline cellulose, povidone, starch, and stearic acid. CLINICAL PHARMACOLOGY Mechanism of Action Carisoprodol: The mechanism of action of carisoprodol in relieving discomfort associated with acute painful musculoskeletal conditions has not been clearly identified. In animal studies, muscle relaxation induced by carisoprodol is associated with altered interneuronal activity in the spinal cord and in the descending reticular formation of the brain. 5 Aspirin: The mechanism of action of aspirin in relieving pain is by inhibition of the body’s production of prostaglandins, which are thought to cause pain sensations by stimulating muscle contractions and dilating blood vessels. Pharmacodynamics Carisoprodol: Carisoprodol is a centrally-acting muscle relaxant that does not directly relax skeletal muscles. A metabolite of carisoprodol, meprobamate, has anxiolytic and sedative properties. The degree to which these properties of meprobamate contribute to the safety and efficacy of carisoprodol is unknown. Aspirin: Aspirin is a non-narcotic analgesic with anti-inflammatory and anti-pyretic activity. Inhibition of prostaglandin biosynthesis appears to account for most of its anti-inflammatory and for at least part of its analgesic and antipyretic properties. In the CNS, aspirin works on the hypothalamus heat-regulating center to reduce fever. Aspirin can cause serious gastrointestinal injury including bleeding, obstruction, and perforations from ulcers possibly by inhibition of the production of prostaglandins, compromising the defenses of the gastric mucosa and the activity of substances involved in tissue repair and ulcer healing (see WARNINGS). Aspirin inhibits platelet aggregation by irreversibly inhibiting prostaglandin cyclo-oxygenase. This effect lasts for the life of the platelet and prevents the formation of the platelet aggregating factor thromboxane A2. Pharmacokinetics Carisoprodol: The pharmacokinetics of carisoprodol and its metabolite meprobamate were studied in a study of 24 healthy subjects (12 male and 12 female) who received single doses of 350 mg of carisoprodol (see Table 1). The Cmax of meprobamate was 2.5 ± 0.5 µg/mL (mean ± SD) after administration of a single 350 mg dose of carisoprodol, which is approximately 30% of the Cmax of meprobamate (approximately 8 µg/mL) after administration of a single 400 mg dose of meprobamate. Table 1. Pharmacokinetic Parameters of Carisoprodol and Meprobamate (Mean ± SD, n=24) carisoprodol meprobamate Cmax (µg/mL) 1.8 ± 1.0 2.5 ± 0.5 AUCinf (µg·hour/mL) 7.0 ± 5.0 46 ± 9.0 Tmax (hour) 1.7 ± 0.8 4.5 ± 1.9 T1/2 (hour) 2.0 ± 0.5 9.6 ± 1.5 Absorption: Absolute bioavailability of carisoprodol has not been determined. After administration of a single dose of 350 mg of carisoprodol, the mean time to peak plasma concentrations (Tmax) of carisoprodol was approximately 1.5 to 2 hours. Co-administration of a high-fat meal with 350 mg of carisoprodol had no effect on the pharmacokinetics of carisoprodol. 6 Metabolism: The major pathway of carisoprodol metabolism is via the liver by cytochrome enzyme CYP2C19 to form meprobamate. This enzyme exhibits genetic polymorphism (see Patients with Reduced CYP2C19 Activity below). Elimination: Carisoprodol is eliminated by both renal and non-renal routes with a terminal elimination half-life of approximately 2 hours after administration of a single dose of 350 mg of carisoprodol. The half-life of meprobamate is approximately 10 hours after administration of a single dose of 350 mg of carisoprodol. Gender: Exposure of carisoprodol is higher in female than in male subjects (approximately 30 to 50% on a weight adjusted basis). Overall exposure of meprobamate is comparable between female and male subjects. Patients with Reduced CYP2C19 Activity: Carisoprodol should be used with caution in patients with reduced CYP2C19 activity. Published studies indicate that patients who are poor CYP2C19 metabolizers have a 4-fold increase in exposure to carisoprodol, and 50% reduced exposure to meprobamate compared to normal CYP2C19 metabolizers. The prevalence of poor metabolizers in Caucasians and African Americans is approximately 3 to 5% and in Asians is approximately 15 to 20%. Aspirin: Absorption: The rate of aspirin absorption from the gastrointestinal (GI) tract is dependent upon the presence or absence of food, gastric pH (the presence or absence of GI antacids), and other physiologic factors. Following absorption, aspirin is hydrolyzed to salicylic acid in the gut wall and during first-pass metabolism with peak plasma levels of salicylic acid occurring within 1 to 2 hours of dosing. Distribution: Salicylic acid is widely distributed to all tissues and fluids in the body including the central nervous system (CNS), breast milk, and fetal tissues. The highest concentrations are found in the plasma, liver, kidneys, heart, and lungs. The protein binding of salicylate is concentration dependent, i.e., nonlinear. At plasma concentrations of salicylic acid < 100 µg/mL and > 400 µg/mL, approximately 90 and 76 percent of plasma salicylate is bound to albumin, respectively. Metabolism: Aspirin, which has a half-life of about 15 minutes, is hydrolyzed in the plasma to salicylic acid such that plasma levels of aspirin may not be detectable 1 to 2 hours after dosing. Salicylic acid, which has a plasma half life of approximately 6 hours, is conjugated in the liver to form salicyluric acid, salicyl phenolic glucuronide, salicyl acyl glucuronide, gentisic acid, and gentisuric acid. At higher serum concentrations of salicylic acid, the total clearance of salicylic acid decreases due to the limited ability of the liver to form both salicyluric acid and phenolic glucuronide. Following toxic doses of aspirin (e.g., > 10 grams), the plasma half-life of salicylic acid may be increased to over 20 hours. 7 Elimination: The elimination of salicylic acid is constant in relation to the plasma salicylic acid concentration. Following therapeutic doses of aspirin, approximately 75, 10, 10, and 5 percent is found excreted in the urine as salicyluric acid, salicylic acid, a phenolic glucuronide of salicylic acid, and an acyl glucuronide of salicylic acid, respectively. As the urinary pH rises above 6.5, the renal clearance of free salicylate increases from less than 5 percent to greater than 80 percent. Alkalinization of the urine is a key concept in the management of salicylate overdose (see OVERDOSAGE, Treatment of Overdosage). Clearance of salicylic acid is also reduced in patients with renal impairment. INDICATIONS AND USAGE Soma Compound is indicated for the relief of discomfort associated with acute, painful musculoskeletal conditions in adults. Soma Compound should only be used for short periods (up to two or three weeks) because adequate evidence of effectiveness for more prolonged use has not been established and because acute, painful musculoskeletal conditions are generally of short duration (see DOSAGE AND ADMINISTRATION). CONTRAINDICATIONS Soma Compound contraindicated in patients with a history of: • a serious GI complication (i.e., bleeding, perforations, obstruction) due to aspirin use • aspirin induced asthma (a symptom complex which occurs in patients who have asthma, rhinosinusitis, and nasal polyps who develop a severe, potentially fatal bronchospasm shortly after taking aspirin or other NSAIDs) • hypersensitivity reaction to a carbamate such as meprobamate • acute intermittent porphyria WARNINGS Carisoprodol: Sedation Carisoprodol hasmay have sedative properties and may impair the mental and/or physical abilities required for the performance of potentially hazardous tasks such as driving a motor vehicle or operating machinery. There have been post-marketing reports of motor vehicle accidents associated with the use of carisoprodol. Since the sedative effects of carisoprodol and other CNS depressants (e.g., alcohol, benzodiazepines, opioids, tricyclic antidepressants) may be additive, appropriate caution should be exercised with patients who take more than one of these CNS depressants simultaneously. Drug Dependence, Withdrawal, and Abuse In the postmarketing experience with carisoprodol, cases of dependence, withdrawal, and abuse have been reported with prolonged use. Most cases of dependence, withdrawal, and abuse occurred in patients who have had a history of addiction or who used carisoprodol in combination with other drugs with abuse potential. However, there have been post-marketing adverse event reports of carisoprodol-associated abuse when used without other drugs with
Load more

Recommended publications
  • Guidelines for the Forensic Analysis of Drugs Facilitating Sexual Assault and Other Criminal Acts
    Vienna International Centre, PO Box 500, 1400 Vienna, Austria Tel.: (+43-1) 26060-0, Fax: (+43-1) 26060-5866, www.unodc.org Guidelines for the Forensic analysis of drugs facilitating sexual assault and other criminal acts United Nations publication Printed in Austria ST/NAR/45 *1186331*V.11-86331—December 2011 —300 Photo credits: UNODC Photo Library, iStock.com/Abel Mitja Varela Laboratory and Scientific Section UNITED NATIONS OFFICE ON DRUGS AND CRIME Vienna Guidelines for the forensic analysis of drugs facilitating sexual assault and other criminal acts UNITED NATIONS New York, 2011 ST/NAR/45 © United Nations, December 2011. All rights reserved. The designations employed and the presentation of material in this publication do not imply the expression of any opinion whatsoever on the part of the Secretariat of the United Nations concerning the legal status of any country, territory, city or area, or of its authorities, or concerning the delimitation of its frontiers or boundaries. This publication has not been formally edited. Publishing production: English, Publishing and Library Section, United Nations Office at Vienna. List of abbreviations . v Acknowledgements .......................................... vii 1. Introduction............................................. 1 1.1. Background ........................................ 1 1.2. Purpose and scope of the manual ...................... 2 2. Investigative and analytical challenges ....................... 5 3 Evidence collection ...................................... 9 3.1. Evidence collection kits .............................. 9 3.2. Sample transfer and storage........................... 10 3.3. Biological samples and sampling ...................... 11 3.4. Other samples ...................................... 12 4. Analytical considerations .................................. 13 4.1. Substances encountered in DFSA and other DFC cases .... 13 4.2. Procedures and analytical strategy...................... 14 4.3. Analytical methodology .............................. 15 4.4.
    [Show full text]
  • Misperceptions About Contraceptives Persist
    30 Women’s Health FAMILY P RACTICE N EWS • September 1, 2008 Misperceptions About Contraceptives Persist BY DOUG BRUNK trauterine device use; 50% thought IUD (SOGC). There may be inadequate in- Oral contraceptives are also safe in women San Diego Bureau failure was a major risk; and fewer than struction with regard to contraception in older than age 35 if they are healthy non- one-third would recommend an IUD as an physician-training programs, she said. smokers, and in women with systemic lu- C ALGARY, ALTA. — Physicians may option for nulliparous women, for post- “Not everybody does IUD insertions, sub- pus erythematosus provided they have no have a surprising number of misconcep- coital contraception, for women with fi- dermal progestin implant, or vasectomy.” antiphospholipid antibodies, vascular dis- tions about birth control, according to re- broids, or for women who had pelvic in- Other barriers to effective contraceptive ease, or nephritis. cent responses to a survey by 96 family flammatory disease within the last year use include exaggerated concerns about Another common exaggerated concern physicians in Kingston, Ont. (Can. Fam. Physician 2008;54:560-6). potential side effects. For example, women is that the use of oral and transdermal Contrary to evidence in the medical lit- “Only 41% of these physicians inserted with diabetes may use oral contraceptives patch contraceptives cause weight gain. erature, more than 60% of respondents IUDs,” Dr. Amanda Black said at the an- if they have no end-organ damage, said Dr. However, a recent Cochrane systematic re- thought pelvic inflammatory disease and nual meeting of the Society of Obstetri- Black of the division of general obstetrics view of randomized, controlled data con- ectopic pregnancy were major risks of in- cians and Gynaecologists of Canada and gynecology at the Ottawa Hospital.
    [Show full text]
  • Forensic Toxicology Laboratory Office of Chief Medical Examiner City of New York
    FORENSIC TOXICOLOGY LABORATORY OFFICE OF CHIEF MEDICAL EXAMINER CITY OF NEW YORK CARISOPRODOL , MEPROBAMATE and TOPIRAMATE by SOLID PHASE EXTRACTION and GAS CHROMATOGRAPHY/MASS SPECTROMETRY (Selected Ion Monitoring) PRINCIPLE Carisoprodol is a carbamate derivative first synthesized in 1959. It is primarily used as a muscle relaxant. UncontrolledMeprobamate is also a carbamate derivative used as a muscle relaxant and the primary metabolite of carisoprodol. Topiramate is a sulfamate-substituted monosaccharide used as an anticonvulsant Carisoprodol, meprobamate and topiramate are quantitated by a selected ion monitoring (SIM) method using methapyrilene as the internal standard. Carisoprodol, meprobamate and topiramate are extracted from biological specimens by solid phase extraction. Drugs are temporarily bound to a sorbent in the solid phase cartridge as the prepared sample is poured through the column. The column is washed to remove interfering compounds, followed by elution of drugs from the column. The eluate is evaporated, reconstituted and injected in the GCMS. Quantitative analysis is performed by SIM GCMS using a six point calibration curve. SAFETY The handling of all biological specimens and reagents is performed within the guidelines which are detailed in the Safety and Health manual. Copy SPECIMEN PREPARATION The procedure is routinely applied to the following biological specimens and their aliquots unless otherwise specified: Blood 0.5 mL of the undiluted specimen Urine 0.5 mL for qualitative identification Brain 0.5 mL of a 1:3 homogenate Gastric Contents 0.5 mL of a 1:10 dilution Liver 0.5 mL of a 1:5 homogenate Vitreous Humor 0.5 mL of the undiluted specimen Bile 0.5 mL of the undiluted specimen Reviewed by: Date: Page 1 of 14 T:\FINALSOP\FINAL SOP PDF\G.
    [Show full text]
  • Metabolism of Drugs in Old Rats (Ii) Metabolism in Vivo and Effect of Drugs in Old Rats
    METABOLISM OF DRUGS IN OLD RATS (II) METABOLISM IN VIVO AND EFFECT OF DRUGS IN OLD RATS RYUICHI KATO AND AKIRA TAKANAKA Department of Pharmacology, National Institute of Hygienic Sciences, Setagaya-ku, Tokyo Received for publication March 16, 1968 It is well known that the effects of some drugs in old animals quite differ from those in young animals. For example, Farner and Verzar (1) observed that the action of am phetamine to increase moter activity was more marked in young rats than in old rats and the action of hexobarbital to antagonized against the amphetamine action was more ef fective in old rats than in young rats. Moreover, the duration of hexobarbital anesthesia was longer in old rats than in young rats (2). Similarly, Petty and Karler (3) observed that anticonvulsive activity of acetazolamide and phenobarbital was more marked in old rats than in young rats. However, there is no study on the mechanism of such altered drug response in rela tion to the rate of drug metabolism. In a previous paper it was reported from our labo ratory that the activities in the oxidation and reduction of drugs and NADPH-linked elec tron transport system in liver microsomes of male and female rats were progressively decreased with aging (4). It is, therefore, of interest to investigate whether or not the metabolism in vivoof vari ous drugs is decreased in old rats in accordance with the decrease in the metabolic activi ties of liver microsomes observed in the in vitro experiments. Moreover, the relationship between the effects of drugs and the rate of in vivo metabolism of drugs in the old rats was studied.
    [Show full text]
  • Assessment of Molecular Action of Direct Gating and Allosteric Modulatory Effects of Carisoprodol (Somartm) on GABA a Receptors
    Graduate Theses, Dissertations, and Problem Reports 2015 Assessment of molecular action of direct gating and allosteric modulatory effects of carisoprodol (SomaRTM) on GABA A receptors Manoj Kumar Follow this and additional works at: https://researchrepository.wvu.edu/etd Recommended Citation Kumar, Manoj, "Assessment of molecular action of direct gating and allosteric modulatory effects of carisoprodol (SomaRTM) on GABA A receptors" (2015). Graduate Theses, Dissertations, and Problem Reports. 6022. https://researchrepository.wvu.edu/etd/6022 This Dissertation is protected by copyright and/or related rights. It has been brought to you by the The Research Repository @ WVU with permission from the rights-holder(s). You are free to use this Dissertation in any way that is permitted by the copyright and related rights legislation that applies to your use. For other uses you must obtain permission from the rights-holder(s) directly, unless additional rights are indicated by a Creative Commons license in the record and/ or on the work itself. This Dissertation has been accepted for inclusion in WVU Graduate Theses, Dissertations, and Problem Reports collection by an authorized administrator of The Research Repository @ WVU. For more information, please contact [email protected]. ASSESSMENT OF MOLECULAR ACTION OF DIRECT GATING AND ALLOSTERIC MODULATORY EFFECTS OF MEPROBAMATE (MILTOWN®) ON GABAA RECEPTORS Manish Kumar, MD, MS Dissertation submitted to the School of Pharmacy at West Virginia University in partial fulfillment of Requirements
    [Show full text]
  • Open PDF File, 64.59 KB, for Carisoprodol Letter
    The Commonwealth of Massachusetts Executive Office of Health and Human Services Office of Medicaid 600 Washington Street Boston, MA 02111 MITT ROMNEY TIMOTHY MURPHY Secretary Governor KERRY HEALEY BETH WALDMAN Medicaid Director Lieutenant Governor September 1, 2005 Dear Prescriber: As of October 3, 2005, all products containing carisoprodol will require prior authorization when prescribed for MassHealth members. This change reflects MassHealth’s and the Drug Utilization Review (DUR) Board’s review of carisoprodol. Carisoprodol has shown limited efficacy in the relief of acute pain associated with musculoskeletal conditions, as an adjunct to rest, physical therapy, and other measures. Carisoprodol does not act directly on the skeletal muscles, but its effects are thought to be related to its sedative properties. Carisoprodol is metabolized to meprobamate, a Schedule IV anxiolytic with a known potential for abuse. According to data collected by the Drug Abuse Warning Network (DAWN), a surveillance system operated by the U.S. Department of Health and Human Services, carisoprodol had a similar abuse pattern to meprobamate. Carisoprodol abuse was often identified in combination with other drugs of abuse such as benzodiazepines, opioid analgesics, alcohol and barbiturates*. Carisoprodol abuse can lead to seizures, coma, and death. The MassHealth Drug List can be found at www.mass.gov/druglist. We would encourage you to review the site because it provides valuable information about the pharmacy benefit for MassHealth members. Specifically, the List lets you know which drugs require prior authorization in the MassHealth program and provides other useful clinical information. We also encourage you to use the MassHealth Web site to subscribe to our service that will automatically send you e-mail alerts when the MassHealth Drug List is updated.
    [Show full text]
  • Carisoprodol (CAS No
    National Toxicology Program Toxicity Report Series Number 56 NTP Technical Report on the Toxicity Studies of Carisoprodol (CAS No. 78-44-4) Administered by Gavage to F344/N Rats and B6C3F1 Mice August 2000 U.S. Department of Health and Human Services Public Health Service National Institutes of Health FOREWORD The National Toxicology Program (NTP) is made up of four charter agencies of the U.S. Department of Health and Human Services (DHHS): the National Cancer Institute (NCI), National Institutes of Health; the National Institute of Environmental Health Sciences (NIEHS), National Institutes of Health; the National Center for Toxicological Research (NCTR), Food and Drug Administration; and the National Institute for Occupational Safety and Health (NIOSH), Centers for Disease Control and Prevention. In July 1981, the Carcinogenesis Bioassay Testing Program, NCI, was transferred to the NIEHS. The NTP coordinates the relevant programs, staff, and resources from these Public Health Service agencies relating to basic and applied research and to biological assay development and validation. The NTP develops, evaluates, and disseminates scientific information about potentially toxic and hazardous chemicals. This knowledge is used for protecting the health of the American people and for the primary prevention of disease. The studies described in this Toxicity Study Report were performed under the direction of the NIEHS and were conducted in compliance with NTP laboratory health and safety requirements and must meet or exceed all applicable federal, state, and local health and safety regulations. Animal care and use were in accordance with the Public Health Service Policy on Humane Care and Use of Animals. These studies are designed and conducted to characterize and evaluate the toxicologic potential of selected chemicals in laboratory animals (usually two species, rats and mice).
    [Show full text]
  • Clinical Pharmacology and Biopharmaceutics Review(S)
    CENTER FOR DRUG EVALUATION AND RESEARCH APPLICATION NUMBER: 200327 CLINICAL PHARMACOLOGY AND BIOPHARMACEUTICS REVIEW(S) CLINICAL PHARMACOLOGY REVIEW NDA: 200-327 Submission Date(s): • 30 Dec 2009 (SDN 1) • 30 Apr 2010 (SDN 14) • 04 Feb 2010 (SDN 7) • 18 Jun 2010 (SDN 19) • 23 Apr 2010 (SDN 10) • 06 Aug 2010 (SDN 31) • 29 Apr 2010 (SDN 13) • 18 Aug 2010 (SDN 34) Drug Ceftaroline Fosamil for Injection Trade Name TEFLARO™ (proposed) OCP Reviewer Aryun Kim, Pharm.D. OCP Team Leader Charles Bonapace, Pharm.D. PM Reviewer Yongheng Zhang, Ph.D. PM Team Leader Pravin Jadhav, Ph.D. OCP Division DCP4 OND division DAIOP (520) Sponsor Cerexa, Inc., Oakland, CA Relevant IND(s) IND 71,371 Submission Type; Code Original New Drug Application (New Molecular Entity), 1S Formulation; Strength(s) Sterile (b) (4) of ceftaroline fosamil and L-arginine supplied as powder in single-use, 20-cc, clear, Type I glass vials containing 600 mg or 400 mg of ceftaroline fosamil Indication For the treatment of complicated skin and skin structure infections (cSSSI) and community-acquired bacterial pneumonia (CABP) caused by designated susceptible isolates of Gram-positive and Gram-negative microorganisms Dosage and 600 mg administered every 12 hours by intravenous infusion over 1 hour Administration in patients ≥18 years of age • for 5-14 days for treatment of cSSSI • for 5-7 days for treatment of CABP 1. EXECUTIVE SUMMARY 5 1.1 Recommendations 5 1.2 Phase 4 Commitments 6 1.3 Summary of Important Clinical Pharmacology and Biopharmaceutics Findings 6 2. QUESTION-BASED REVIEW 11 2.1 General Attributes of the Drug 11 2.2 General Clinical Pharmacology 13 2.3 Intrinsic Factors 37 2.4 Extrinsic Factors 56 2.5 General Biopharmaceutics 58 2.6 Analytical Section 58 3.
    [Show full text]
  • Chapter 329 [New] Uniform Controlled Substances Act
    CHAPTER 329 [NEW] UNIFORM CONTROLLED SUBSTANCES ACT Part I. General Provisions Section 329-1 Definitions 329-2 Hawaii advisory commission on drug abuse and controlled substances; number; appointment 329-3 Annual report 329-4 Duties of the commission Part II. Standards and Schedules 329-11 Authority to schedule controlled substances 329-12 Nomenclature 329-13 Schedule I tests 329-14 Schedule I 329-15 Schedule II tests 329-16 Schedule II 329-17 Schedule III Tests 329-18 Schedule III 329-19 Schedule IV tests 329-20 Schedule IV 329-21 Schedule V tests 329-22 Schedule V 329-23 Republishing and distribution of schedules Part III. Regulation of Manufacture, Distribution, Prescription, and Dispensing of Controlled Substances 329-31 Rules 329-31.5 Clinics 329-32 Registration requirements 329-33 Registration 329-34 Revocation and suspension of registration 329-35 Order to show cause 329-36 Records of registrants 329-37 Filing requirements 329-38 Prescriptions 329-39 Labels 329-40 Methadone treatment programs Part IV. Offenses and Penalties 329-41 Prohibited acts B-penalties 329-42 Prohibited acts C-penalties 329-43 Penalties under other laws 329-43.5 Prohibited acts related to drug paraphernalia Amended 0612 1 329-44 Notice of conviction to be sent to licensing board, department of commerce and consumer affairs 329-45 Repealed 329-46 Prohibited acts related to visits to more than one practitioner to obtain controlled substance prescriptions 329-49 Administrative penalties 329-50 Injunctive relief Part V. Enforcement and Administrative Provisions 329-51 Powers of enforcement personnel 329-52 Administrative inspections 329-53 Injunctions 329-54 Cooperative arrangements and confidentiality 329-55 Forfeitures 329-56 Burden of proof; liabilities 329-57 Judicial review 329-58 Education and research 329-59 Controlled substance registration revolving fund; established Part VI.
    [Show full text]
  • Urine Drug Toxicology and Pain Management Testing
    Urine Drug Toxicology and Pain Management Testing Kara Lynch, PhD, DABCC University of California San Francisco San Francisco, CA Learning Objectives • Describe what chronic pain is, who is affected and how they are commonly treated • Explain the common methodologies used in pain management testing • Interpret urine drug testing results • Create protocols to minimize the occurrence of false positive or false negative results Pain – definition and types • Pain - an unpleasant sensory and emotional experience associated with actual or potential tissue damage • Chronic pain - pain that extends beyond the expected period of healing • Nociceptive Pain – Pain caused by tissue injury – Stimulus-evoked, high intensity – Opioid sensitive • Neuropathic Pain – Caused by nerve injury – Spontaneous activity – Develops in days or month – Opioid insensitive Chronic Pain Patients • Arthritis • Fibromyalgia – Osteoarthritis • Headaches – Rheumatoid arthritis – Migraine – Gout – Tension • Cancer – Cluster • Chronic non-cancer pain • Myofascial pain • Central pain syndrome • Neuropathic pain – CNS damage – Diabetic Peripheral – Multiple Sclerosis Neuropathy – Parkinson’s disease – Postherpetic neuralgia • Chronic abnominal pain • Neck and Back Pain – Intestinal obstructions Chronic Pain Medications • Opiates • Synthetic opioids – Codeine – Fentanyl – Morphine – Methadone • Semi-synthetic opioids – Meperidine – Oxymorphone – Tramadol – Oxycodone – Propoxyphene – Hydromorphone – Levorphanol – Hydrocodone – Tapentadol – Buprenorphine • Anticonvulsant • Muscle
    [Show full text]
  • 2021 Formulary List of Covered Prescription Drugs
    2021 Formulary List of covered prescription drugs This drug list applies to all Individual HMO products and the following Small Group HMO products: Sharp Platinum 90 Performance HMO, Sharp Platinum 90 Performance HMO AI-AN, Sharp Platinum 90 Premier HMO, Sharp Platinum 90 Premier HMO AI-AN, Sharp Gold 80 Performance HMO, Sharp Gold 80 Performance HMO AI-AN, Sharp Gold 80 Premier HMO, Sharp Gold 80 Premier HMO AI-AN, Sharp Silver 70 Performance HMO, Sharp Silver 70 Performance HMO AI-AN, Sharp Silver 70 Premier HMO, Sharp Silver 70 Premier HMO AI-AN, Sharp Silver 73 Performance HMO, Sharp Silver 73 Premier HMO, Sharp Silver 87 Performance HMO, Sharp Silver 87 Premier HMO, Sharp Silver 94 Performance HMO, Sharp Silver 94 Premier HMO, Sharp Bronze 60 Performance HMO, Sharp Bronze 60 Performance HMO AI-AN, Sharp Bronze 60 Premier HDHP HMO, Sharp Bronze 60 Premier HDHP HMO AI-AN, Sharp Minimum Coverage Performance HMO, Sharp $0 Cost Share Performance HMO AI-AN, Sharp $0 Cost Share Premier HMO AI-AN, Sharp Silver 70 Off Exchange Performance HMO, Sharp Silver 70 Off Exchange Premier HMO, Sharp Performance Platinum 90 HMO 0/15 + Child Dental, Sharp Premier Platinum 90 HMO 0/20 + Child Dental, Sharp Performance Gold 80 HMO 350 /25 + Child Dental, Sharp Premier Gold 80 HMO 250/35 + Child Dental, Sharp Performance Silver 70 HMO 2250/50 + Child Dental, Sharp Premier Silver 70 HMO 2250/55 + Child Dental, Sharp Premier Silver 70 HDHP HMO 2500/20% + Child Dental, Sharp Performance Bronze 60 HMO 6300/65 + Child Dental, Sharp Premier Bronze 60 HDHP HMO
    [Show full text]
  • Medical Examiners Commission for Presentation in This Report
    FLORIDA DEPARTMENT OF LAW ENFORCEMENT APRIL 2016 Data Collection The State of Florida’s Bureau of Vital Statistics reported 100,189 deaths occurred in Florida during the first six months of 2015. Of the cases seen by the state’s medical examiners, toxicology results determined that the drugs listed below were present at the time of death in 4,682 cases. The medical examiners assessed whether the drug(s) identified was the cause of death or merely present at the time of death. The data were then submitted to the Medical Examiners Commission for presentation in this report. It is important to note that each death is a single case, while each time a drug is detected represents an occurrence. The vast majority of the 4,682 cases (decedents) had more than one drug occurrence. When reporting the data, the state’s medical examiners were asked to distinguish between the drugs determined to be the cause of death, and those drugs that were present in the body at the time of death. A drug is indicated as the cause of death only when, after examining all evidence, the autopsy, and toxicology results, the medical examiner determines the drug played a causal role in the death. It is not uncommon for a decedent to have multiple drugs listed as a cause of death. However, a drug may not have played a causal role in the death even when the medical examiner determines the drug is present or identifiable in the decedent. Therefore, a decedent often is found to have multiple drugs listed as present; these are drug occurrences and are not equivalent to cases (decedents).
    [Show full text]